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超高分辨率元素/同位素质量 spectrometry(m/Δm > 1,000,000):液体取样-常压辉光放电与轨道阱质谱联用在生物化学和环境分析中的应用。

Ultra-High Resolution Elemental/Isotopic Mass Spectrometry (m/Δm > 1,000,000): Coupling of the Liquid Sampling-Atmospheric Pressure Glow Discharge with an Orbitrap Mass Spectrometer for Applications in Biological Chemistry and Environmental Analysis.

机构信息

Department of Chemistry, Clemson University, Clemson, SC, 29634, USA.

CNRS, Institute for Analytical & Physical Chemistry of the Environment & Materials, UPPA, IPREM, UMR 5254, Helioparc 2, Av Pr Angot, F-64053, Pau, France.

出版信息

J Am Soc Mass Spectrom. 2019 Jul;30(7):1163-1168. doi: 10.1007/s13361-019-02183-w. Epub 2019 Apr 18.

Abstract

Many fundamental questions of astrophysics, biochemistry, and geology rely on the ability to accurately and precisely measure the mass and abundance of isotopes. Taken a step further, the capacity to perform such measurements on intact molecules provides insights into processes in diverse biological systems. Described here is the coupling of a combined atomic and molecular (CAM) ionization source, the liquid sampling-atmospheric pressure glow discharge (LS-APGD) microplasma, with a commercially available ThermoScientific Fusion Lumos mass spectrometer. Demonstrated for the first time is the ionization and isotopically resolved fingerprinting of a long-postulated, but never mass-spectrometrically observed, bi-metallic complex Hg:Se-cysteine. Such a complex has been implicated as having a role in observations of Hg detoxification by selenoproteins/amino acids. Demonstrated as well is the ability to mass spectrometrically-resolve the geochronologically important isobaric Sr and Rb species (Δm ~ 0.3 mDa, mass resolution m/Δm ≈ 1,700,000). The mass difference in this case reflects the beta-decay of the Rb to the stable Sr isotope. These two demonstrations highlight what may be a significant change in bioinorganic and atomic mass spectrometry, with impact expected across a broad spectrum of the physical, biological, and geological sciences. Graphical Abstract "".

摘要

许多天体物理学、生物化学和地质学的基本问题都依赖于准确、精确测量同位素质量和丰度的能力。更进一步说,能够对完整分子进行此类测量,为研究各种生物系统中的过程提供了深入的了解。本文描述了一种组合原子和分子(CAM)电离源——液体取样常压辉光放电(LS-APGD)微等离子体与市售 ThermoScientific Fusion Lumos 质谱仪的耦合。本文首次展示了一种长期假设但从未通过质谱观察到的双金属配合物 Hg:Se-半胱氨酸的电离和同位素分辨指纹图谱。这种配合物被认为在观察硒蛋白/氨基酸对汞解毒的过程中起作用。本文还展示了对地质年代学上重要的等质量同位素 Sr 和 Rb 物种(Δm ~ 0.3 mDa,质量分辨率 m/Δm ≈ 1,700,000)进行质谱分辨的能力。在这种情况下,质量差异反映了 Rb 通过β衰变到稳定的 Sr 同位素。这两个演示突出了生物无机和原子质谱学可能发生的重大变化,预计将对物理、生物和地质科学的广泛领域产生影响。

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